Laminated fitting for heat exchanger

ABSTRACT

An end fitting for a serpentine heat exchanger couples an inlet or outlet port to a pair of flat tubes comprising the heat exchange core. The fitting comprises three laminated plates and a nipple coupled to an opening in the outermost of the plates. The inner plate is a header plate with slots for receiving the flat tubing. A spacer plate interconnects the outer and inner plates and has an aperture shaped to couple the port to the slots for defining a fluid flow path. The plates are stamped from aluminum sheet stock clad with a brazing alloy. The plates are assembled and secured by a steel rivet and the nipple is attached. The parts are joined by brazing. The fitting can be brazed to the exchanger core at the same time.

FIELD OF THE INVENTION

This invention relates to a fitting and the method of making a fittingfor a heat exchanger and particularly to a laminated fitting.

BACKGROUND OF THE INVENTION

It is common practice to construct heat exchangers with one or moretubes to conduct a working fluid through a long and sometimes tortuouspath to obtain heat transfer between the working fluid and the ambientfluid surrounding the tubes. It has been recognized that pathscomprising two tubes in parallel impose a smaller pressure drop betweenthe inlet and outlet of the heat exchanger with resulting improvement insystem efficiency.

The chief tube designs which have evolved for heat exchanger use are around tube and a flat or oval tube. The tubes are connected to input andoutput ports which generally take the form of a round stub pipe ornipple, the connections being perfected by special fittings adapted tothe particular heat exchanger design. It is always important that thefittings enhance system integrity. For that reason the fittings musthave a high burst pressure when used with high pressure systems.

When a heat exchanger employs round tubes, two parallel paths areaccommodated by a fitting formed of a round tube bent in a U-shape toengage the ends of both tubular paths and a tubular tee branch formingthe port at the bend of the U. This fitting has been quite successful.On the other hand, when flat or oval tubes are used for parallel paths adesign using a U-shaped flat tube for joining the path ends has theweakness that the internal pressure tends to deform the flat tube into around shape. The consequential strain at the joints results in a lowburst pressure of the fitting. It is thus desired to provide a fittingfor plural flat tubes having a high burst pressure.

SUMMARY OF THE INVENTION

It is therefore an object of the invention to provide a fitting for flattubes which has a high burst pressure. It is another object to providesuch a fitting which is readily coupled to a heat exchanger. It is alsoan object of the invention to provide a method of making such a fitting.

The invention is carried out by a fitting for coupling to a flat tubeserpentine heat exchanger comprising; tube coupling means comprising afirst plate having perforation means shaped to conform to and receiveflat tubing, spacer means comprising a second plate having an openingcommunicating with the perforation means and a margin surrounding theopening, the spacer means being bonded at its margin to the first plate,a third plate bonded to the margin of the second plate and having a portin communication with the opening in the spacer means, and tubularconduit means secured to the port in the third plate, whereby a fluidflow passage is provided between the conduit means and the perforationmeans.

The invention is further carried out by the method of making a fittingfor a heat exchanger having flat tubing comprising the step of; stampingfrom sheet stock first, second and third flat plates, forming at leastone slot shaped aperture in the first plate to conform to flat heatexchanger tubing, forming an opening in the second plate, forming a portopening in the third plate, stacking the first, second and third plateswith the second plate between the first and third plates and the secondplate opening communicating with the port opening and the aperture, andbonding the plates at portions outboard of the respective openings andapertures.

cl BRIEF DESCRIPTION OF THE DRAWINGS

The above and other advantages of the invention will become moreapparent from the following description taken in conjunction with theaccompanying drawings wherein like references refer to like parts andwherein:

FIG. 1 is an elevational view of a serpentine heat exchanger withfittings according to the invention.

FIG. 2 is a component of a fitting of FIG. 1 comprising a first platefor coupling to heat exchanger tubing.

FIG. 3, is a component of a fitting of FIG. 1 comprising a second plate.

FIG. 4 is a component of a fitting of FIG. 1 comprising a third platefor coupling to an inlet or outlet nipple.

FIG. 5 is a partially sectioned view of the fitting of FIG. 1.

DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1 illustrates an application of the fittings of the invention. Afitting 10 is attached to each end of a serpentine heat exchanger 12 toprovide inlet and outlet ports. The heat exchanger 12 comprises a spacedpair of flat aluminum tubes 14 connected in parallel and shaped in aserpentine pattern having many loops, although two loops are shown. Analuminum air center 16 bridges the space between the tubes andfacilitates heat transfer to the surrounding air. The heat exchanger 12may have more than two tubes 14 or only one, however two tubes is thepreferred design and the fitting of the invention will be described inthat context. It will be apparent, however, that the invention is notlimited to a fitting for two tubes. In the same way, the preferred heatexchanger material is aluminum and the fitting is preferably composedchiefly of aluminum parts but the invention is not limited to thatmaterial. The function of the fittings 10 is to couple the flat heatexchanger tubes to round external fluid conduits and requires leak freeconnections, high burst pressure and efficient flow distribution to andfrom the tubes.

FIGS. 2, 3 and 4 show components and FIG. 5 shows an assembly of thefitting 10 which meets these needs. A generally rectangular plate 18 hasa pair of elongated holes or slots 20 spaced to align with the flattubes 14 of the heat exchanger. The slots 20 are sized to conform to theperiphery of the tubes 14 so that the tubes may be inserted into theslots 20 and bonded to the plate 18. A plate 22 of the same outer sizeand shape as the plate 18 has a central round port opening 24 forreceiving a nipple 26 which is the port of the fitting for either inletor outlet purposes and extends from one side of the plate 22. A spacerplate 28, also of the same outer size and shape as the plate 18 has agenerally H-shaped opening 30 covering an area surrounding the opening24 and extending substantially over the slots 20 in the plate 18. Themargin 32 of the plate 28 outboard of the opening 30 is in contact withthe adjoining surfaces of the plates 18 and 22. Each side of theH-shaped opening 30 has a small nib 34 projecting toward the center ofthe opening by an amount sufficient to overlap the slots 20. These nibs34 serve as stops to prevent intrusion of the heat exchanger tubes 14into the opening 30 when the fitting is applied to a heat exchanger. Themargin 32 has fingers 36 extending inwardly between the slots 20 tooverlap the opening 22 a small amount to form a stop for the nipple 26when it is inserted into the opening 24 of the plate 22. The fingers 36also increases the area of the plate 28 in contact with both plates 18and 22. As a matter of design this is desirable since it reduces theunit loading on the plates 18 and 20. The plates 18, 22 and 28 have twoaligned holes 38 on opposite sides of the port opening 24. Rivets 40extend through the holes to mechanically secure the parts upon assemblyuntil the plates are bonded together. The rivets may be steel or othermaterial having a lower coefficient of expansion than aluminum. Theadjoining interfaces of the plates are bonded at the margin 32 bybrazing and the nipple 26 is joined to the opening 24 in the same way.The material used for the plates is aluminum 3003 sheet stock 0.125 inchthick, and clad with a coating of aluminum 4343 on at least the plates18 and 22.

It will thus be seen that the fitting meets the requirement of highburst pressure since the slotted plate 18 has ample strength to resistthe lateral forces on the flat tubing 14 when under pressure from theworking fluid of the heat exchanger. In addition, the flow distributionbetween the port and the tubing 14 is optimized by the design of theplate 28 which acts as a spacer between the plates 18 and 22. Thethickness of the spacer can be chosen as a matter of design with theexpense and weight offsetting any advantages of a thicker spacer. Thespecific shape of the stamped opening 30 is also a matter of choice, notdictated by fabrication economics.

In the manufacture of the fitting 10 the plates 18, 22 and 28 arestamped from plate aluminum stock and the slots 20 and openings 24 and30 are stamped out. Preferably the stock for at least the plates 18 and22 is clad with aluminum brazing alloy so that the adjoining platesurfaces can be brazed without additional brazing material. The platesare degreased, coated with flux and then stacked in the proper order andheld together by the rivets 40; the nipple 26 is assembled to theopening 24. The fingers 36 prevent the nipple from being inserted toofar into the stack. Preferably the assembly is then coupled to the endsof tubes 14. The nibs 34 extending from the margin 32 over the slots 22prevent the tubes 14 from entering too far into the fitting. Theassembly is brazed using a method that is well known for brazingaluminum heat exchangers. The heat exchangers can be processed in largebatches by heating to just the right temperature so that the brazingalloy melts and flows to secure the junction points of the parts. Due todifferential expansion of the rivets and the aluminum when heated tobrazing temperature, the rivets 40 provide contact force between thealuminum plates to enhance the bonding process. In the case of thenipple 26 and the tubes 14, the brazing alloy on the surface of theplates runs into the interfaces to form leak free bonds.

It will thus be seen that fittings resistant to deformation by highpressure can be fabricated by economical methods.

The embodiments of the invention in which an exclusive property orprivilege is claimed are defined as follows:
 1. A fitting for couplingto a flat tube serpentine heat exchanger comprising; a flat tube, tubecoupling means comprising a first flat plate of uniform thickness havingperforation means shaped to conform to and receive said flat tube,spacer means comprising a second flat plate of uniform thickness havingan opening communicating with the perforation means and a marginsurrounding the opening, the spacer means being bonded at its margin tothe first plate, a third flat plate of uniform thickness beyond to themargin of the second plate and having a port in communication with theopening in the spacer means, and tubular conduit means secured to theport in the third plate, whereby a fluid flow passage is providedbetween the conduit means and the perforation means, and the margin ofthe spacer means having inwarding extending stop means partiallycovering both the perforation means and the port to prevent both theflat tube and the conduit means from extending into the tube couplingmeans past the respective first plate and third plate to facilitatetheir proper assembly.
 2. A fitting for coupling to a flat tubeserpentine heat exchanger comprising; at least two flat tubes, tubecoupling means comprising a first flat plate of uniform thickness havings lot shaped perforations shaped to conform to and receive the flattubes, spacer means comprising a second flat plate of uniform thicknesshaving an opening communicating with the perforations, the opening beingdefined by a margin surrounding the opening and the perforations, thespacer means being bonded at its margin to the first plate, a third flatplate of uniform thickness bonded to the margin of the second plate andhaving a port in communication with the opening in the spacer means, anipple secured to the port in the third plate, whereby a fluid flowpassage is provided between the nipple and the perforations, and themargin of the spacer means having inwarding extending stop meanspartially covering both the perforations and the port to prevent boththe flat tubes and the nipple from extending into the tube couplingmeans past the respective first plate and third plate to facilitatetheir proper assembly.
 3. The invention as defined in claim 1 whereinthe stop means is a nib for the flat tube and a finger for the tubularconduit means.
 4. The invention as defined in claim 1 wherein rivetshaving a lower coefficient of expansion than the plates secure theplates together to facilitate their bonding.